Gas analyzing apparatus

ABSTRACT

There is provided a gas analyzing apparatus capable of minimizing gas remaining by integrating gas switching apparatuses into one and capable of analyzing impurities of ppb level to sub-ppb level contained in various kinds of high-purity gases efficiently and accurately. The gas analyzing apparatus comprises an analyzer introduction passage  22  for introducing a sample gas supplied from a sample gas source  11  into an analyzer  12  via an analyzer introduction valve  22 V; a separator introduction passage  23  diverging from a first side passage of the analyzer introduction valve  22 V for introducing a sample gas into a separator  13  via a separator introduction valve  23 V; a separator flowing out passage  24  for introducing the sample gas flowing out from the separator  13  into a second side passage of the analyzer introduction valve  22 V via a separator flowing-out valve  24 V; and a gas switching apparatus to be such formed that when the analyzer introduction valve  22 V is opened, the separator introduction valve  23 V and the separator flowing-out valve  24 V are connectively operated to be closed, and when the analyzer introduction valve  22 V is closed, the separator introduction valve  23 V and the separator flowing-out valve  24 V are connectively operated to be opened.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a gas analyzing apparatus, moreparticularly to a gas analyzing apparatus capable of analyzingimpurities of ppb level to sub-ppb level contained in various kinds ofhigh-purity gases with one analyzer.

2. Description of the Prior Art

In a semiconductor-manufacturing field, since trace impurities inhigh-purity gas to be used have a bad effect on device performance, itis necessary to observe the trace impurities. As a means for analyzingvarious kinds of impurities of ppb level to ppt level present inhigh-purity gas, an apparatus has been used recently where a separatorsuch as a gas chromatography or the like and an analyzer such as anatmospheric pressure ionization mass spectrometer (APIMS) are combined.

In the apparatus where the separator and the analyzer are thus combined,for example, as shown in the systematic diagram of FIG. 4, there arecases where a sample gas supplied from a sample gas source 11 isdirectly analyzed in the analyzer 12, and the sample gas is alsoanalyzed in the analyzer 12 after major components and impurities of thesample gas are separated in a separator 13. In the above apparatus, itis necessary to introduce a sample gas from the sample gas source byswitching to the direction of the analyzer 12 and to the direction ofthe separator 13 in a first gas switching apparatus 14 of a sample gasinlet side, and at the same time, to introduce the sample gas toward theanalyzer 12 by switching to the direction of a direct introduction andto the direction of the separator in a second switching apparatus 15 ofa sample gas flowing-out side.

That is to say, when the sample gas is directly analyzed in the analyzer12, a shut off valve 14 a is opened and a shut off valve 14 b is closedin the first gas switching apparatus 14 while a shut off valve 15 a isopened and a shut off valve 15 b is closed in the second gas switchingapparatus 15. Furthermore, when the analysis of the sample gas iscarried out via the separator 13, the shut off valve 14 a is closed andthe shut off valve 14 b is opened in the first gas switching apparatus14 while the shut off valve 15 a is closed and the shut of valve 15 b isopened in the second gas switching apparatus 15. Furthermore, when theseparator 13 is not used during the analysis, a carrier gas supplied tothe separator 13 from a carrier gas source 16 is exhausted to theoutside from an exhaust valve 17 provided in an outlet passage of theseparator 13.

However, according to the construction as above-mentioned, two gasswitching apparatuses must be used. Moreover, the opening and closing ofthe shut off valves of both the gas switching apparatuses are requiredto connectively operate. Furthermore, when the separator 13 is used,since a gas passage between both the gas switching apparatuses becomes acondition that the sample gas is shut up and stays therein, it isimpossible to carry out the gas switching swiftly. Furthermore, there issuch an occasion that analysis results are badly influenced byadsorption/desorption of the sample gas components to/from an innersurface of piping.

SUMMARY OF THE INVENTION

Therefore, the object of the present invention is to provide a gasanalyzing apparatus capable of minimizing gas remaining by integratingthe gas switching apparatuses into one, and capable of analyzingimpurities of ppb level to sub-ppb level contained in various kinds ofhigh-purity gases efficiently and accurately with one analyzer.

To achieve the above object, according to the present invention, thereis provided a gas analyzing apparatus comprising a separator such as agas chromatograph or the like for separating gas components and ananalyzer such as an atmospheric-pressure ionization mass spectrometer orthe like for analyzing gas components, the gas analyzing apparatuscomprising: an analyzer introduction passage for directly introducing a;sample gas supplied from a sample gas source into the analyzer via ananalyzer introduction valve; a separator introduction passage divergingfrom a first side passage of the analyzer introduction valve forintroducing a sample gas into the separator via a separator introductionvalve; a separator flowing-out passage for introducing the sample gasflowing out from the separator into a second side passage of theanalyzer introduction valve via a separator flowing-out valve; and a gasswitching apparatus to be such formed that when the analyzerintroduction valve is opened, the separator introduction valve and theseparator flowing-out valve are connectively operated to be closed, andwhen the analyzer introduction valve is closed, the separatorintroduction valve and the separator flowing-out valve are connectivelyoperated to be opened.

In particular, according to the gas analyzing apparatus of the presentinvention, the gas switching apparatus comprises a purge passage towhich a first side passage of said separator flowing-out valve and asecond side passage of said separator introduction valve are connectedvia a purge valve which is opened and closed simultaneously with saidanalyzer introduction valve.

Furthermore, according to the gas switching apparatus of the presentinvention, the gas switching apparatus is a 4-connected 4-way valvewhere respective valves and passages thereof are integrally formed.

Furthermore, according to the present invention, there is provided a gasanalyzing apparatus comprising a separator such as a gas chromatographor the like for separating gas components, an analyzer such as anatmospheric-pressure ionization mass spectrometer or the like foranalyzing gas components, a sample gas source for supplying a samplegas, and a carrier gas source for supplying a carrier gas into saidseparator, said gas analyzing apparatus comprising: a gas switchingapparatus comprising: an analyzer introduction passage to which a samplegas passage connected to said sample gas source and an analyzer inletpassage connected to said analyzer are connected via an analyzerintroduction valve; a separator introduction passage to which saidsample gas passage and a separator inlet passage are connected via aseparator introduction valve; a separator flowing-out passage to which aseparator outlet passage and said analyzer inlet passage are connectedvia a separator flowing-out valve; and a purge passage to which saidseparator outlet passage and a separator inlet passage are connected viaa purge valve; wherein said gas switching apparatus is such operatedthat when said sample gas from said sample gas source is directlyintroduced into said analyzer, said analyzer introduction valve and saidpurge valve are opened together while said separator introduction valveand said separator flowing-out valve are closed together thereby saidsample gas from said sample gas source is directly introduced into saidanalyzer via said analyzer introduction passage while a carrier gassupplied from said carrier gas source into said separator and flowingout from said separator outlet passage is introduced into said separatorinlet passage via said purge passage, and when said sample gas from saidsample gas source is introduced into said analyzer after said sample gasis separated in said separator, said analyzer introduction valve andsaid purge valve are closed together while said separator introductionvalve and said separator flowing-out valve are opened together therebysaid sample gas from said sample gas source is introduced into saidseparator through said separator introduction passage to be separated insaid separator and then is accompanied by said carrier gas to flow outfrom said separator outlet passage and then introduced into saidanalyzer inlet passage through said separator flowing-out passage.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 is a systematic diagram showing the first embodiment of a gasanalyzing apparatus according to the present invention;

FIG. 2 is a is a systematic diagram showing the second embodiment of thegas analyzing apparatus according to the present invention;

FIG. 3 is a systematic diagram showing the third embodiment of the gasanalyzing apparatus according to the present invention; and

FIG. 4 is a systematic diagram showing a conventional analyzingapparatus where a separator and an analyzer are combined.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 is a systematic diagram showing the first embodiment of a gasanalyzing apparatus according to the present invention. In the gasanalyzing apparatus where a separator 13 such as a gas chromatograph orthe like and an analyzer 12 such as an atmospheric-pressure ionizationmass spectrometer are combined via a gas switching apparatus 21, anoperation to analyze a sample gas supplied from a sample gas source 11by directly introducing the sample gas to the analyzer 12 and anoperation to analyze a sample gas in the analyzer 12 after the samplegas is introduced into the separator 13 for separating gas componentsthereof, are switched by switching the gas passages of the gas switchingapparatus 21.

The gas switching apparatus 21 used in this embodiment is an integratedvalve, so called, 3-connected 4-way valve comprising an analyzerintroduction passage 22 for directly introducing the sample gas suppliedfrom the sample gas source 11 by a sample gas passage 51 into ananalyzer inlet passage 52 connected to the analyzer 12 via an analyzerintroduction valve,22V, a separator introduction passage 23 divergingfrom a first side passage 22 a of the analyzer introduction valve 22Vfor introducing the sample gas from a separator inlet passage 53 intothe separator 13 via a separator introduction valve 23V, a separatorflowing-out passage 24 for introducing the gas flowing out from theseparator 13 to a separator outlet passage 54 into a second side passage22 b of the analyzer introduction valve 22V via a separator flowing-outvalve 24V and then for introducing the gas into the analyzer 12 via theanalyzer inlet passage 52.

The gas switching apparatus 21 is such formed that the separatorintroduction valve 23V and the separator flowing-out valve 24V aresimultaneously operated with the analyzer introduction. valve 22V, andsuch that when the analyzer introduction valve 22V is opened, theseparator introduction valve 23V and the separator flowing-out valve 24Vare closed together. Furthermore, an exhaust valve 17 for exhausting acarrier gas supplied into the separator 13 from a carrier gas source 16is provided in the separator outlet passage 54.

When the sample gas is directly analyzed in the analyzer 12, theanalyzer introduction valve 22V of the gas switching apparatus 21 isopened. Connectively operating to this, the separator introduction valve23V and the separator flowing-out valve 24V are closed together and inaddition, the exhaust valve 17 is opened. Thus, the sample gas suppliedinto the gas switching apparatus 21 from the sample gas source 11 passesthrough the analyzer introduction valve 22V and is introduced into theanalyzer 12 from the analyzer inlet passage 52 via the analyzerintroduction passage 22, thereby a predetermined analyzing operation iscarried out in the analyzer 12. At this time, the carrier gas suppliedinto the separator 13 and flowing out into the separator outlet passage54 is exhausted into the outside from the exhaust valve 17.

Furthermore, when the analysis is carried out in the analyzer 12 aftergas components are separated in the separator 13, the analyzerintroduction valve 22V and the exhaust valve 17 are closed. Connectivelyoperating, the separator introduction valve 23V and the separatorflowing-out valve 24V are opened together. Thus, the sample gas suppliedfrom the sample gas source 11 passes through the separator introductionvalve 23V and is introduced into the separator 13 from the Separatorintroduction passage 23 via the separator inlet passage 53, thereby thesample gas is measured in a sampling portion 13 a of the separator 13.After a predetermined separating operation is carried out in aseparating column provided in the separator 13, the measured sample gasis accompanied by a predetermined amount of the carrier gas suppliedfrom the carrier gas source 16 to be introduced into the separatoroutlet passage 54 from the separator 13 and then, introduced into thesecond side passage 22 b of the analyzer introduction valve 22V throughthe separator flowing-out valve 24V of the separator flowing-out passage24 to thereby be introduced into the analyzer 12 via the analyzer inletpassage 52. In the gas switching apparatus 21 thus formed, since onlyone analyzer introduction valve 22V is provided in the analyzerintroduction passage 22 to be used in the direct analysis, even thoughthe analyzer introduction valve 22V is closed when the sample gas isseparated in the separator 13, there is no case where the sample gas isshut up and stays, and adsorption/desorption of the remaining gas doesnot occur. Therefore, it is possible to accurately and swiftly carry outa continuous measurement by gas switching. Furthermore, it is possibleto obtain a simple, space-saving and low-cost gas switching apparatus bedecreasing the number of valves compared to the conventional apparatus.

FIG. 2 is a systematic diagram showing the second embodiment of the gasanalyzing apparatus according to the present invention, which uses acarrier gas (the gas exhausted into the outside in the first embodiment)as a purge gas of the separator 13. In addition, the same referencenumerals will be used for the same elements as in the first embodimentin the following explanation, and the detailed description thereaboutwill be omitted.

That is to say, similarly to the first embodiment, in addition to theanalyzer introduction passage 22 having the analyzer introduction valve22V and the separator introduction passage 23 having the separatorintroduction valve 23V and the separator following-out passage 24 havingthe separator flowing-out valve 24V, a gas switching apparatus 31 to beused in this embodiment is formed so that a first side passage 24 a ofthe separator flowing-out valve 24V and a second side passage 23 b ofthe separator introduction valve 23V are connected to a purge passage 25having a purge valve 25V which is opened and closed simultaneously withthe analyzer introduction valve 22V.

When the sample gas is directly analyzed in the analyzer 12, theanalyzer introduction valve 22V and the purge valve 25V are openedtogether and the separator introduction valve 23V and the separatorflowing-out valve 24V are closed together. Since the separatorflowing-out valve 24V is closed, the carrier gas supplied from thecarrier gas source 16 flows from the first side passage 24 a into thepurge passage 25 and is introduced into the second side passage 23 b ofthe separator introduction valve 23V through the purge valve 25V. Sincethe separator introduction valve 23V is closed, the carrier gas isintroduced from the separator introduction passage 23 into the separator13 and then, exhausted into the outside from an exhaust passage 13 bthrough the sampling portion 13 a.

Furthermore, when the analysis is carried out by using the separator 13,the analyzer introduction valve 22V and the purge valve 25V are closedand the separator introduction valve 23V and the separator flowing-outvalve 24V are opened. The sample gas from the sample gas source 11passes through the separator introduction valve 23V and is introducedfrom the separator introduction passage 23 into the separator 13 to bemeasured in the sampling portion 13 a. After a predetermined separatingoperation is carried out, the sample gas is accompanied by the carriergas from the carrier gas source 16 to flow out from the separator 13 andis introduced into the second side passage 22 b of the analyzerintroduction valve 22V through the separator flowing-out valve 24V ofthe separator flowing-out passage 24 and then, introduced into theanalyzer 12 via the analyzer introduction passage 22.

Therefore, when the analysis is carried out by using the separator 13,the sample gas flows into a passage including the sampling portion 13 aof the separator 13, and when the sample gas is directly analyzed in theanalyzer 12 without using the separator 13, the carrier gas is made toflow into the passage 22 b. That is to say, a gas which is notintroduced into the analyzer 12 is always made to flow into the samplingportion 13 a of the separator 13. There is no case where the samplinggas remains in the passage including the sampling portion 13 a.Furthermore, it is possible to securely prevent air from flowingbackward to the sampling portion 13 a from the exhaust passage 13 b viaan exhaust piping. Moreover, there becomes is no case where the samplingportion 13 a or an inside of a passage reaching thereto is contaminatedby remaining gas or air.

Thus, it is possible to accurately and swiftly carry out the continuousmeasurement by gas switching. At this time, even though all the gasremaining portions are not minimized in the respective passages in thegas switching apparatus 31, it is preferable that a gas remainingportion G1 when the sample gas flows from the separator introductionvalve 23V into the sampling portion 13 a is made smaller. Even though agas remaining portion G2 when the carrier gas flows into the samplingportion 13 a is made relatively larger, the analysis is little affectedby this.

FIG. 3 is a systematic diagram showing the third embodiment of the gasanalyzing apparatus according to the present invention. Similar to thegas switching apparatus 31 shown in the above second embodiment, a gasswitching apparatus 41 shown in this embodiment comprises the analyzerintroduction passage 22 having the analyzer introduction valve 22V, theseparator introduction passage 23 having the separator introductionvalve 23V, the separator flowing-out passage 24 having the separatorflowing-out valve 24V, and the purge passage 25 having the purge valve25 a. In the gas switching apparatus 41 of this embodiment, thearrangement of the respective valves is designed such that theconnecting portions of the respective passages become shortest.

That is to say, by arranging the respective valves at an equal distanceand at an angle of 90° and making junctions of the respective passagesin the gas switching apparatus 41 to come as close to the valves aspossible, gas remaining portions when the opening and closing of thevalves are switched are made to be minimized.

By minimizing-all the gas remaining portions like this, even when pluralkinds of the sample gases are switched to be analyzed, it is possible toprevent a sample gas of the previous analysis from being detected asimpurity in the next analysis of another sample gas.

For example, in the gas switching apparatus 41 of the third embodiment,assume the sample gas is oxygen and the carrier gas is helium andimpurities in oxygen are analyzed. At first, in the initial state of thegas switching apparatus 41, since the separator introduction valve 23Vand the separator flowing-out valve 24V are opened and the analyzerintroduction valve 22V and the purge valve 25V are closed, oxygen as thesample gas from the sample gas source 11 flows into the gas switchingapparatus 41 and passes through the separation introduction valve 23Vand then, flows from the separator introduction passage 23 into theseparator 13 to thereby be introduced into the sampling portion 13 a. Atthis time, helium as the carrier gas supplied from the carrier gassource 16 to the separator 13 is introduced into the analyzer 12 fromthe separator flowing-out passage 24 through the separator flowing-outvalve 24V.

The impurities to be analyzed, which are contained in the sample gassampled in the sampling portion 13 a and are separated in the separator13, are accompanied by the carrier gas to flow out from the separator 13and pass through the separator flowing-out valve 24V of the gasswitching apparatus 41 and then, are introduced into the analyzer 12from the separator flowing-out passage 24 to thereby be analyzed.

Next, the gas switching operation is carried out. That is to say, theseparator introduction valve 23V and the separator flowing-out valve 24Vof the gas switching apparatus 41 are closed and at the same time, theanalyzer introduction valve 22V and the purge valve 25V are opened.Thus, oxygen from the sample gas source 11 passes through the analyzerintroduction valve 22V and is introduced into the analyzer 12 from theanalyzer introduction passage 22, thereby impurities in oxygen aredirectly analyzed. At this time, helium flowing out from the separator13 flows toward the sampling portion 13 a through the purge valve 25V tothereby be exhausted form the exhaust passage 13 b.

Therefore, since any one of oxygen as the sample gas or helium as thecarrier gas is continuously supplied into the analyzer 12 and theseparator 13 without stopping, it is possible to avoid contamination dueto the back flow of the air to the sampling portion 13 a oradsorption/desorption due to the gas remaining.

At this time, even though the gas remaining portions of the gasswitching apparatus 31 shown in the second embodiment are larger thanthose of the gas switching apparatus 41 shown in the third embodiment,since the flowing carrier gas is not an impurity to be analyzed which iscapable of having a bad effect on the analysis but rather is a gas forwhich it is difficult to have an effect on the analysis and aims at apage of the passage including the sampling portion 13 a, an effect onthe analysis of the gas remaining portions is minimized in the gasswitching apparatus 31.

By returning to the initial state after finishing the direct analysis ofoxygen, it is possible to carry out the analysis again by using theseparator 13. Thus, by controlling the respective shut off valves of thegas switching apparatus, it is possible to carry out the gas switchingbetween the direct analysis and the separating analysis of the samplegas accurately and swiftly.

As described above, according to the gas analyzing apparatus of thepresent invention, it is possible to effectively, swiftly and securelycarry out the operation to directly analyze impurities in the samplegas, and the operation to analyze them after separating major componentsand impurities by using the separator such as a gas chromatograph or thelike, with one analyzing apparatus. Furthermore, since the introductionpassage of the sample gas is one, it is possible to calibrate for thedirect introduction analysis and the separating analysis with onecalibration apparatus.

What is claimed is:
 1. A gas analyzing apparatus comprising a separatorsuch as a gas chromatograph or the like for separating components and ananalyzer such as an atmospheric-pressure ionization mass spectrometer orthe like for analyzing gas components, said gas analyzing apparatusfurther comprising: an analyzer introduction passage for directlyintroducing a sample gas supplied from a sample gas source into saidanalyzer via an analyzer introduction valve; a separator introductionpassage diverging from a first side passage of said analyzerintroduction valve for introducing said sample gas into said separatorvia a separator introduction valve; a separator flowing-out passage forintroducing at least some of said sample gas flowing out from saidseparator into a second side passage of said analyzer introduction valvevia a separator flowing-out valve; and a valve for blocking or passingcarrier gas supplied from a carrier gas source; wherein, when saidanalyzer introduction valve and said blocking or passing carrier gasvalve are operated to be opened, said separator introduction valve andsaid separator flowing-out valve are connectively operated to be closed,and when said analyzer introduction valve and said blocking or passingcarrier gas valve are operated to be closed, said separator introductionvalve and said separator flowing-out valve are connectively operated tobe opened.
 2. The gas analyzing apparatus of claim 1, wherein said gasswitching apparatus comprises: a purge passage to which a first sidepassage of said separator flowing-out valve and a second side passage ofsaid separator introduction valve are connected via said blocking orpassing carrier gas valve.
 3. The gas analyzing apparatus of claim 1wherein said analyzer introduction valve, said separator introductionvalve, said separator flowing-out valve and said blocking or passingcarrier gas valve are formed as a 4-connected 4-way valve.